Air-filtering protection device

ABSTRACT

An air-filtering protection device includes a filtering mask and an actuating and sensing device. The filtering mask is made of a graphene-doping material and wearable to filter air and includes a first coupling element. The actuating and sensing device includes a second coupling element. The second coupling element is engaged with the first coupling element of the filtering mask for allowing the actuating and sensing device to be detachably mounted on the filtering mask. The actuating and sensing device includes at least one senor, at least one actuating device, a microprocessor, a power controller and a data transceiver. The at least one actuating device is disposed on one side of the at least one sensor and includes at least one guiding channel. The actuating device is enabled to transport an air to flow toward the sensor through the guiding channel so as to make the air sensed by the sensor.

FIELD OF THE INVENTION

The present disclosure relates to an air-filtering protection device, and more particularly to an air-filtering protection device capable of combining with an actuating and sensing device for monitoring the environment.

BACKGROUND OF THE INVENTION

Nowadays, people pay much attention to the devices and methods of monitoring the air quality in the environment. For example, it is important to monitor carbon monoxide, carbon dioxide, volatile organic compounds (VOC), PM2.5, and so on. The exposure of these substances in the environment will cause human health problems or even harm the life. Therefore, it is important for every country to develop and implement the environmental monitoring technology.

As known, portable electronic devices are widely used and applied in the modem life. In addition, the portable electronic devices are indispensable electronic devices. Accordingly, it is feasible to use the portable electronic device to monitor the ambient air. If the portable electronic device is capable of immediately providing people with the monitored data relating to the environment for caution, it may help people escape or prevent from the injury and influence on human health caused by the exposure of the substances described above in the environment. In other words, the portable electronic device is suitably used for monitoring the ambient air in the environment.

Although it is obviously beneficial to make the portable electronic device equipped with environmental sensor for collecting environment data, however, when the environmental sensor is integrated into the electronic device, the monitoring sensitivity and the precision of the environmental sensor should be taken into consideration. For example, the environmental sensor is in contact with the air circulating from the outside and transferred by naturally occurring convection in the surroundings. In other words, the environmental sensor fails to fetch a consistent airflow to maintain stably monitoring. Since it is difficult to trigger response action of the environmental sensor by the circulating air transferred by convection, the response time of the environmental sensor is long and becomes a great factor affecting real-time monitoring.

As mentioned above, the portable electronic device is suitably used for monitoring the ambient air in the environment. Therefore, there is a need of providing an air-filtering protection device combining with an actuating and sensing device for monitoring the environment and enabling a protection mechanism immediately when the air quality is poor.

SUMMARY OF THE INVENTION

An object of the present disclosure provides an air-filtering protection device combining with an actuating and sensing device for monitoring the environment. The air-filtering protection device is worn by a user to enclose the air in the mouth and nose of the user. The actuating and sensing device is enabled to circulate the air and the air enclosed by the air-filtering protection device could be discharged by the circulation. That is, the enablement of the actuating and sensing device enforces the air circulation in the air-filtering protection device, so that the polluted air in the air-filtering protection device could be exhausted, and the temperature and the humidity of the air could be adjusted by means of exchanging of the air inside and outside of the air-filtering protection device.

Another object of the present disclosure provides an air-filtering protection device combining with an actuating and sensing device for monitoring the environment. Since the air enclosed by the air-filtering protection device is monitored by a sensor of the actuating and sensing device, the air quality inside the air-filtering protection device could be monitored.

A further object of the present disclosure provides an air-filtering protection device combining with an actuating and sensing device for monitoring the environment. The circulation of the air inside the air-filtering protection device could be adjusted to generate different flow rates (e.g. amount of air exhausting) in accordance with the condition of the air quality thereof. Therefore, the air quality inside the air-filtering protection device could be adjusted. When the sensor monitors that the air quality inside the air-filtering protection device is a lasting harm to human beings, a notification signal for replacing a new filtering mask of the air-filtering protection device is issued to the user.

A further object of the present disclosure provides an air-filtering protection device combining with an actuating and sensing device for monitoring the environment. The actuating and sensing device could be detachably mounted on the filtering mask to form an independent and portable actuating and sensing module for monitoring the air quality. Namely, the actuating and sensing device could monitor the air quality outside the filtering mask and transmit an output data of the monitored data to a connection device. The information carried in the output data may be displayed, stored and transmitted by the connection device. Consequently, the real-time information may be displayed and a real-time notification may be formed. Moreover, the output data could be uploaded for constructing a cloud database to enable an air quality notification mechanism and an air quality processing mechanism. Therefore, the user could wear the air-filtering protection device immediately to prevent from the ill influence on human health caused by the air pollution.

In accordance with an aspect of the present disclosure, an air-filtering protection device is provided. The air-filtering protection device includes a filtering mask and an actuating and sensing device. The filtering mask is made of a graphene-doping material and is adapted to be worn to filter air. The filtering mask includes a first coupling element and the actuating and sensing device includes a second coupling element. The second coupling element is engaged with the first coupling element of the filtering mask for allowing the actuating and sensing device to be detachably mounted on the filtering mask. The actuating and sensing device comprises at least one senor, at least one actuating device, a microprocessor, a power controller and a data transceiver. The at least one actuating device is disposed on one side of the at least one sensor. The at least one actuating device comprises at least one guiding channel. The at least one actuating device is enabled to transport an air to flow toward the at least one sensor through the at least one guiding channel so as to make the air sensed by the at least one sensor.

The above contents of the present disclosure will become more readily apparent to those ordinarily skilled in the art after reviewing the following detailed description and accompanying drawings, in which:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a schematic perspective view illustrating the outer appearance of an air-filtering protection device according to an embodiment of the present disclosure;

FIG. 1B is a schematic partial exploded view illustrating the air-filtering protection device of FIG. 1A;

FIG. 2A is a schematic cross-sectional view illustrating the actuating and sensing device of the air-filtering protection device of FIG. 1A;

FIG. 2B is a schematic perspective view illustrating the outer appearance of the actuating and sensing device of the air-filtering protection device of FIG. 2A;

FIG. 2C is an enlarged cross-sectional view illustrating the actuating and sensing device of the air filtering protection device of FIG. 2A;

FIG. 2D is a schematic cross-sectional view illustrating the actions of the fluid actuating device of the actuating and sensing device of the air filtering protection device of FIG. 2A;

FIG. 3A is a schematic exploded view illustrating a fluid actuating device of the present disclosure;

FIG. 3B is a schematic exploded view illustrating the fluid actuating device of FIG. 3A and taken along another viewpoint;

FIG. 4 is a schematic cross-sectional view illustrating the piezoelectric actuator of the fluid actuating device as shown in FIGS. 3A and 3B;

FIG. 5 is a schematic cross-sectional view illustrating the fluid actuating device as shown in FIGS. 3A and 3B;

FIGS. 6A to 6E schematically illustrate the actions of the fluid actuating device according to the embodiment of the present disclosure; and

FIG. 7 schematically illustrates the architecture of a driving and information transmitting system for the actuating and sensing device according to an embodiment of the present disclosure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present disclosure will now be described more specifically with reference to the following embodiments. It is to be noted that the following descriptions of preferred embodiments of this invention are presented herein for purpose of illustration and description only. It is not intended to be exhaustive or to be limited to the precise form disclosed.

Please refer to FIGS. 1A and 1B. The present disclosure provides an air-filtering protection device including at least one filtering mask 2, at least one first coupling element 21, at least one actuating and sensing device 1, at least one second coupling element 10, at least one sensor 12, at least one actuating device 13, at least one microprocessor 14, at least one power controller 15, at least one data transceiver 16, at least one guiding channel 17 and at least one air. The number of the filtering mask 2, the first coupling element 21, the actuating and sensing device 1, the second coupling element 10, the microprocessor 14, the power controller 15, the data transceiver 16, the guiding channel 17 and the air is exemplified by one for each in the following embodiments but not limited thereto. It is noted that each of the filtering mask 2, the first coupling element 21, the actuating and sensing device 1, the second coupling element 10, the microprocessor 14, the power controller 15, the data transceiver 16, the guiding channel 17 and the air can also be provided in plural numbers.

Please refer to FIGS. 1A and 1B. The air-filtering protection device of the present disclosure includes a filtering mask 2 and an actuating and sensing device 1. The filtering mask 2, which is made of the graphene-doping material, is worn by a user and used to filter air. For example, the filtering mask 2 may be a mouth mask, which has a covering surface made of a non-woven cloth doped with graphene, for filtering air, or the filtering mask 2 may be a wearable face mask, which has a filtering element made of the graphene-doping material for filtering air. Moreover, the filtering mask 2 includes a first coupling element 21. The first coupling element 21 may be a fastening element having one or more tenon 211. The first coupling element 21 has a first air channel 212 running through the inner surface and the outer surface of the filtering mask 2. A filtering element 213 is disposed in the first air channel 212 to seal the first air channel 212 so as to filter air. Consequently, the filtering mask 2 is adapted to be worn by the user to cover the mouth and nose of the user completely for achieving the function of filtering air. The actuating and sensing device 1 includes a second coupling element 10. The second coupling element 10 may be a fastening element with one or more recess 101 and one or more engaging slot 102. The recess 101 is in communication with the engaging slot 102. The second coupling element 10 includes a second air channel 103 in fluid communication with the interior of the actuating and sensing device 1 for allowing the air to be introduced into the interior of the actuating and sensing device 1.

For mounting and positioning the actuating and sensing device 1 on the filtering mask 2, the recess 101 of the second coupling element 10 is aligned with the tenon 211 of the first coupling element 21, and then the second coupling element 10 is rotated along a locking direction for allowing the tenon 211 of the first coupling element 21 to be fitted into the engaging slot 102 of the second coupling element 10. Consequently, the actuating and sensing device 1 is mounted and positioned on the filtering mask 2. Namely, the tenon 211 of the first coupling element 21 is engaged with the corresponding engaging slot 102 of the second coupling element 10 so that the actuating and sensing device 1 is mounted and positioned on the filtering mask 2 by engagement. On the contrary, after the second coupling element 10 is rotated along an unlocking direction, the recess 101 of the second coupling element 10 is aligned with the tenon 211 of the first coupling element 21 for disengaging the second coupling element 10 from the first coupling element 21. Consequently, the actuating and sensing device 1 is disassembled from the filtering mask 2. Therefore, the actuating and sensing device 1 is detachable and forms an independent and portable actuating and sensing module for monitoring the air quality.

Please refer to FIG. 7. The actuating and sensing device 1 includes at least one sensor 12, at least one actuating device 13, a microprocessor 14, a power controller 15 and a data transceiver 16. The power controller 15 receives energy and transfers the energy to the sensor 12 and the actuating device 13 to enable the sensor 12 and the actuating device 13. The data transceiver 16 receives and transmits signal.

An example of the sensor 12 includes but is not limited to a temperature sensor, a volatile organic compound sensor (e.g., a sensor for measuring formaldehyde or ammonia gas), a particulate sensor (e.g., a PM2.5 particle sensor), a carbon monoxide sensor, a carbon dioxide sensor, an oxygen sensor, an ozone sensor, any other appropriate gas sensor, a humidity sensor, a water content sensor, a substance sensor (e.g., a sensor for measuring compounds or biological substances in liquid or air), a water quality sensor, any other appropriate liquid sensor, a light sensor, or the combination thereof. Alternatively, the sensor 12 includes but is not limited to a virus sensor, a bacterial sensor, a microbiological sensor or the combination thereof. Alternatively, the sensor 12 includes a graphene-sensor for detecting biomarker, which is operable to detect the concentration of nitrite in human exhaled breath.

The actuating device 13 is a driving device capable of driving a desired system in response to a control signal. An example of the actuating device 13 includes but is not limited to an electric actuating device, a magnetic actuating device, a thermal actuating device, a piezoelectric actuating device, a fluid actuating device or the combination thereof. For example, the electric actuating device is an electric actuating device of a DC motor, an AC motor or a step motor, the magnetic actuating device is an magnetic actuating device of a magnetic coil motor, the thermal actuating device is a thermal actuating device of a heat pump, the piezoelectric actuating device is a piezoelectric actuating device of a piezoelectric pump, and the fluid actuating device is a fluid actuating device of a gas pump or a liquid pump.

Please refer to FIGS. 2A, 2B, 2C and 2D. The sensor 12 and the actuating device 13 are integrated together to form a modular structure. The actuating device 13 is disposed on one side of the sensor 12. The actuating device 13 includes at least one guiding channel 17. When the actuating device 13 is enabled to transport the air, the air is transferred through the guiding channel 17 and flows toward the sensor 12. Consequently, the air is sensed by the sensor 12. Since the air is guided to the sensor 12 by the actuating device 13 and the sensor 12 is provided with a stable and uniform amount of the air continuously, the time for enabling the sensor 12 to monitor the air is largely reduced, thereby achieving the monitoring of the air more precisely.

Please refer to FIGS. 2A, 2B, 2C and 2D again. The actuating and sensing device 1 further includes a carrier 11, which is a platform for integrating the sensor 12 with the actuating device 13. For example, the carrier 11 may be a substrate such as a printed circuit board (PCB). An array of the sensor 12 and the actuating device 13 may be disposed on the carrier 11. In a variant example, the carrier 11 may be an application-specific integrated circuit (ASIC). In another variant example, the carrier 11 may be a system on chip (SOC). The sensor 12 is deposited on the carrier 11. The actuating device 13 is packaged on the carrier 11. It is noted that the carrier 11 is not limited to the above-mentioned embodiments and may be other platform for integrating the sensor 12 and the actuating device 13.

In an embodiment, the actuating device 13 is a fluid actuating device. The fluid actuating device 13 may be a driving structure of a piezoelectric pump or a driving structure of a micro-electro-mechanical system (MEMS) pump. Hereinafter, the actions of the fluid actuating device 13 of a piezoelectric pump will be described as follows.

Please refer to FIGS. 3A and 3B. The fluid actuating device 13 includes a gas inlet plate 131, a resonance plate 132, a piezoelectric actuator 133, a first insulation plate 134 a, a conducting plate 135 and a second insulation plate 134 b. The piezoelectric actuator 133 is aligned with the resonance plate 132. The gas inlet plate 131, the resonance plate 132, the piezoelectric actuator 133, the first insulation plate 134 a, the conducting plate 135 and the second insulation plate 134 b are stacked on each other sequentially. After the above components are combined together, the cross-sectional view of the resulting structure of the fluid actuating device 13 is shown in FIG. 5.

The gas inlet plate 131 includes at least one inlet 131 a. Preferably but not exclusively, the gas inlet plate 131 includes four inlets 131 a. The inlets 131 a run through the gas inlet plate 131. In response to the action of the atmospheric pressure, the air can be introduced into the fluid actuating device 13 through the at least one inlet 131 a. Moreover, at least one convergence channel 131 b is formed on a first surface of the gas inlet plate 131, and is in communication with the at least one inlet 131 a on a second surface of the gas inlet plate 131. Moreover, a central cavity 131 c is located at the intersection of the convergence channels 131 b. The central cavity 131 c is in communication with the at least one convergence channel 131 b such that the air from the at least one inlet 131 a would be introduced into the at least one convergence channel 131 b and is guided to the central cavity 131 c. In this embodiment, the at least one inlet 131 a, the at least one convergence channel 131 b and the central cavity 131 c of the gas inlet plate 131 are integrally formed from a single structure. The central cavity 131 c forms a convergence chamber for temporarily storing the air. In some embodiments, the gas inlet plate 131 may be, for example, made of stainless steel. Moreover, the depth of the convergence chamber defined by the central cavity 131 c may be equal to the depth of the at least one convergence channel 131 b. The resonance plate 132 may be made of, but not limited to a flexible material. The resonance plate 132 has a central aperture 132 c aligned with the central cavity 131 c of the gas inlet plate 131 which allows the air to be transferred therethrough. In other embodiments, the resonance plate 132 may be, for example, made of copper.

The piezoelectric actuator 133 includes a suspension plate 1331, an outer frame 1332, at least one bracket 1333 and a piezoelectric plate 1334. The piezoelectric plate 1334 is attached on a first surface 1331 c of the suspension plate 1331. In response to an applied voltage, the piezoelectric plate 1334 is subjected to a deformation. When the piezoelectric plate 1334 is subjected to the deformation, it facilitates a bending vibration of the suspension plate 1331. In this embodiment, the at least one bracket 1333 is connected between the suspension plate 1331 and the outer frame 1332, while the two ends of the bracket 1333 are connected with the outer frame 1332 and the suspension plate 1331 respectively that the bracket 1333 can elastically support the suspension plate 1331. At least one vacant space 1335 is formed between the bracket 1333, the suspension plate 1331 and the outer frame 1332. The at least one vacant space 1335 is in communication with the guiding channel 17 for allowing the air to go through. The type of the suspension plate 1331 and the outer frame 1332 and the type and the number of the at least one bracket 1333 may be varied according to the practical requirements. The outer frame 1332 is arranged around the suspension plate 1331. Moreover, a conducting pin 133 c is protruded outwardly from the outer frame 1332 so as to be electrically connected with an external circuit (not shown).

As shown in FIG. 4, the suspension plate 1331 has a bulge 1331 a that makes the suspension plate 1331 a stepped structure. The bulge 1331 a is formed on a second surface 1331 b of the suspension plate 1331. The bulge 1331 a may be a circular convex structure. A top surface of the bulge 1331 a of the suspension plate 1331 is coplanar with a second surface 1332 a of the outer frame 1332, while the second surface 1331 b of the suspension plate 1331 is coplanar with a second surface 1333 a of the bracket 1333. Moreover, there is a specific depth from the bulge 1331 a of the suspension plate 1331 (or the second surface 1332 a of the outer frame 1332) to the second surface 1331 b of the suspension plate 1331 (or the second surface 1333 a of the bracket 1333). A first surface 1331 c of the suspension plate 1331, a first surface 1332 b of the outer frame 1332 and a first surface 1333 b of the bracket 1333 are coplanar with each other. The piezoelectric plate 1334 is attached on the first surface 1331 c of the suspension plate 1331. In some other embodiments, the suspension plate 1331 may be a square plate structure with two flat surfaces, but the type of the suspension plate 1331 may be varied according to the practical requirements. In this embodiment, the suspension plate 1331, the at least one bracket 1333 and the outer frame 1332 may be integrally formed from a metal plate (e.g., a stainless steel plate). In an embodiment, the length of a side of the piezoelectric plate 1334 is smaller than the length of a side of the suspension plate 1331. In another embodiment, the length of a side of the piezoelectric plate 1334 is equal to the length of a side of the suspension plate 1331. Similarly, the piezoelectric plate 1334 is a square plate structure corresponding to the suspension plate 1331 in terms of the design.

In this embodiment, the first insulation plate 134 a, the conducting plate 135 and the second insulation plate 134 b of the fluid actuating device 13 are stacked on each other sequentially and located under the piezoelectric actuator 133, as shown in FIG. 3A. The profiles of the first insulation plate 134 a, the conducting plate 135 and the second insulation plate 134 b substantially match the profile of the outer frame 1332 of the piezoelectric actuator 133. In some embodiment, the first insulation plate 134 a and the second insulation plate 134 b may be made of an insulating material (e.g. a plastic material) for providing insulating efficacy. In other embodiment, the conducting plate 135 may be made of an electrically conductive material (e.g. a metallic material) for providing electrically conducting efficacy. In this embodiment, the conducting plate 135 may have a conducting pin 135 a disposed thereon so as to be electrically connected with an external circuit (not shown).

Please refer to FIG. 5. In an embodiment, the gas inlet plate 131, the resonance plate 132, the piezoelectric actuator 133, the first insulation plate 134 a, the conducting plate 135 and the second insulation plate 134 b of the fluid actuating device 13 are stacked on each other sequentially. Moreover, there is a gap h between the resonance plate 132 and the outer frame 1332 of the piezoelectric actuator 133. In this embodiment, the gap h between the resonance plate 132 and the outer frame 1332 of the piezoelectric actuator 133 may be filled with a filler (e.g. a conductive adhesive) so that a depth from the resonance plate 132 to the bulge 1331 a of the suspension plate 1331 of the piezoelectric actuator 133 can be maintained. The gap h ensures the proper distance between the resonance plate 132 and the bulge 1331 a of the suspension plate 1331 of the piezoelectric actuator 133, so that the air can be transferred quickly, the contact interference is reduced and the generated noise is largely reduced. In some embodiments, alternatively, the height of the outer frame 1332 of the piezoelectric actuator 133 is increased, so that a gap is formed between the resonance plate 132 and the piezoelectric actuator 133.

Please refer to FIGS. 2C, 2D, 3A, 3B and 5. After the gas inlet plate 131, the resonance plate 132 and the piezoelectric actuator 133 are combined together, a movable part 132 a and a fixed part 132 b of the resonance plate 132 are defined. The movable part 132 a is around the central aperture 132 c. A convergence chamber for converging the air is defined by the movable part 132 a of the resonance plate 132 and the gas inlet plate 131 collaboratively. Moreover, a first chamber 130 is formed between the resonance plate 132 and the piezoelectric actuator 133 for temporarily storing the air. Through the central aperture 132 c of the resonance plate 132, the first chamber 130 is in communication with the central cavity 131 c of the gas inlet plate 131. The peripheral regions of the first chamber 130 are in communication with the guiding channel 17 through the vacant space 1335 between the brackets 1333 of the piezoelectric actuator 133.

Please refer to FIGS. 2C, 2D, 3A, 3B, 5 and FIGS. 6A to 6E. The actions of the fluid actuating device 13 will be described as follows. When the fluid actuating device 13 is enabled, the piezoelectric actuator 133 vibrates along a vertical direction in a reciprocating manner by using the bracket 1333 as a fulcrum. Please refer to FIG. 6A. Since the resonance plate 132 is light and thin, the resonance plate 132 vibrates along the vertical direction in the reciprocating manner because of the resonance of the piezoelectric actuator 133 in response to the applied voltage. More especially, a region of the resonance plate 132 spatially corresponding to the central cavity 131 c of the gas inlet plate 131 is also subjected to a bending deformation. The region of the resonance plate 132 corresponding to the central cavity 131 c of the gas inlet plate 131 is the movable part 132 a of the resonance plate 132. When the piezoelectric actuator 133 vibrates downwardly, the movable part 132 a of the resonance plate 132 is subjected to the bending deformation because the movable part 132 a of the resonance plate 132 is pushed by the air and vibrates in response to the piezoelectric actuator 133. In response to the downward vibration of the piezoelectric actuator 133, the air is fed into the at least one inlet 131 a of the gas inlet plate 131. Then, the air is transferred to the central cavity 131 c of the gas inlet plate 131 through the at least one convergence channel 131 b. Then, the air is transferred through the central aperture 132 c of the resonance plate 132 spatially corresponding to the central cavity 131 c, and introduced downwardly into the first chamber 130. As the piezoelectric actuator 133 is enabled, the resonance of the resonance plate 132 occurs. Consequently, the resonance plate 132 vibrates along the vertical direction in the reciprocating manner. As shown in FIG. 6B, during the vibration of the movable part 132 a of the resonance plate 132 at this stage, the movable part 132 a of the resonance plate 132 moves down to contact and attach on the bulge 1331 a of the suspension plate 1331 of the piezoelectric actuator 133, and a distance from the fixed part 132 b of the resonance plate 132 to a region of the suspension plate 1331 except the bulge 1331 a remains the same. Owing to the deformation of the resonance plate 132 described above, a middle communication space of the first chamber 130 is closed, and the volume of the first chamber 130 is compressed. Under this circumstance, the pressure gradient occurs to push the air in the first chamber 130 moving toward peripheral regions of the first chamber 130, and flowing downwardly through the vacant space 1335 of the piezoelectric actuator 133. Referring to FIG. 6C, the movable part 132 a of the resonance plate 132 returns to its original position when the piezoelectric actuator 133 vibrates upwardly. Consequently, the volume of the first chamber 130 is continuously compressed to generate the pressure gradient which makes the air in the first chamber 130 continuously pushed toward peripheral regions. Meanwhile, the air is continuously fed into the at least one inlet 131 a of the gas inlet plate 131, and transferred to the central cavity 131 c. Then, as shown in FIG. 6D, the resonance plate 132 moves upwardly, which is cause by the resonance of upward motion of the piezoelectric actuator 133. That is, the movable part 132 a of the resonance plate 132 is also vibrated upwardly. Consequently, it decreases the current of the air from the at least one inlet 131 a of the gas inlet plate 131 into the central cavity 131 c. At last, as shown in FIG. 6E, the movable part 132 a of the resonance plate 132 has returned to its original position. As the embodiments described above, when the resonance plate 132 vibrates along the vertical direction in the reciprocating manner, the gap h between the resonance plate 132 and the piezoelectric actuator 133 is helpful to increase the maximum displacement along the vertical direction during the vibration. In other words, the configuration of the gap h between the resonance plate 132 and the piezoelectric actuator 133 can increase the amplitude of vibration of the resonance plate 132. Consequently, a pressure gradient is generated in the guiding channels of the fluid actuating device 13 to facilitate the air to flow at a high speed. Moreover, since there is an impedance difference between the feeding direction and the exiting direction, the air can be transmitted from the inlet side to the outlet side. Even if a gas pressure (which may impede the air flow) exist at the outlet side, the fluid actuating device 13 still has the capability of pushing the air to the guiding channel 17 while achieving the silent efficacy. The steps of FIGS. 6A to 6E may be done repeatedly. Consequently, air circulation is generated in which the ambient air is transferred from the outside to the inside by the fluid actuating device 13.

As mentioned above, the actions of the fluid actuating device 13 is further described as below. The gas inlet plate 131, the resonance plate 132, the piezoelectric actuator 133, the first insulation plate 134 a, the conducting plate 135 and the second insulation plate 134 b are sequentially stacked. As shown in FIGS. 2C and 2D, the fluid actuating device 13 is disposed on the carrier 11 and the guiding channel 17 is formed between the fluid actuating device 13 and the carrier 11. The guiding channel 17 is disposed on one side of the sensor 12. The fluid actuating device 13 is enabled to transport the air, and allows the air to be exhausted through the guiding channel 17 along the direction indicated by the arrow (see FIG. 2D), by which the air is directly guided to the sensor 12 at a stable flowrate. Consequently, the sensor 12 can monitor the air directly and acquire the accurate sensing results. Moreover, the time for enabling the sensor 12 to monitor the air is largely reduced, thereby achieving the monitoring of the air more precisely.

As shown in FIG. 7, the power controller 15 of the actuating and sensing device 1 is used to store and output energy. The power controller 15 transfers the energy to the sensor 12 and the actuating device 13 for powering the sensor 12 to perform a sensing operation and powering the actuating device 13 to perform an actuating operation under control. The actuating and sensing device 1 may not be equipped with a power source itself. Rather, the actuating and sensing device 1 may be coupled to an external power supply device 3 for energy transfer, thereby enabling the sensor 12 and the actuating device 13. Accordingly, the configuration described above saves a lot of space when installing the entire module, and the purpose of minimizing the design of the module is achieved.

As mentioned above, the power controller 15 transfers the energy to power the sensor 12 and the actuating device 13 through the power supply device 3. In an embodiment, the power supply device 3 may transfer the energy to the power controller 15 through a wired transmission path. For example, the power supply device 3 is a charger or a chargeable battery, and the power supply device 3 may transfer the energy to the power controller 15 through the wired transmission path. Alternatively, the power supply device 3 may transfer the energy to the power controller 15 through a wireless transmission path. For example, the power supply device 3 is a charger or a chargeable battery, both of which has a wireless charging component (or an induction charging component), and the power supply device 3 may transfer the energy to the power controller 15 through the wireless transmission path. In another embodiment, the power supply device 3 is a portable electronic device with wireless charging/discharging function (e.g., a smart phone). For example, the smart phone has a wireless charging component (or an induction charging component), and the smart phone may transfer the energy to the power controller 15 through the wireless transmission path.

In an embodiment, the power controller 15 further includes a chargeable element (not shown) capable of receiving and storing the energy. The chargeable element of the power controller 15 may receive and store the energy from the power supply device 3 through the wired transmission path or the wireless transmission path. Then, the energy may be transferred to the sensor 12 and the actuating device 13 for powering the sensor 12 to perform a sensing operation and powering the actuating device 13 to perform an actuating operation under control.

The microprocessor 14 processes and calculates the monitored data transmitted from the sensor 12 to convert the monitored data into an output data. The data transceiver 16 may receive and transmit the output data to the connection device 4 through transmission, so that the connection device 4 may display and store the information carried by the output data, or transmit the information carried by the output data to a storage device (not shown) for storing or processing. In an embodiment, the connection device 4 is in connection with a notification processing system 5 to actively (i.e. directly notify) or passively (i.e. operated by a user who reads the information carried by the output data) enable an air quality notification mechanism, e.g., an instant air quality map informing people to avoid away or wear masks. In another embodiment, the connection device 4 is in connection with a notification processing device 6 to actively (i.e. directly operate) or passively (i.e. operated by a user who reads the information carried by the output data) enable an air quality processing mechanism, e.g., an air cleaner or an air-conditioner is enabled to clean the air.

In an embodiment, the connection device 4 is a display device with a wired communication module (e.g., a desktop computer). In another embodiment, the connection device 4 is a display device with a wireless communication module (e.g., a notebook computer). In another embodiment, the connection device 4 is a portable electronic device with a wireless communication module (e.g., a mobile phone). For example, the wired communication module may have an RS485 communication port, an RS232 communication port, a Modbus communication port or a KNX communication port for wired communication. The wireless communication module may perform wireless communication through a Zigbee communication technology, a Z-wave communication technology, an RF communication technology, a Bluetooth communication technology, a Wifi communication technology or an EnOcean communication technology.

A driving and information transmitting system for the actuating and sensing device 1 further includes a networking relay station 7 and a cloud data processor 8. The connection device 4 is used to transmit the information carried by the output data to the networking relay station 7. Then, the information carried by the output data is transmitted from the networking relay station 7 to the cloud data processor 8 to be stored and processed. After the information carried by the output data is processed by the cloud data processor 8, the cloud data processor 8 issues a notification signal to the connection device 4 through the networking relay station 7. After the connection device 4 receives the notification signal, the notification processing system 5 connected with the connection device 4 receives the notification signal from the connection device 4, and accordingly enables an air quality notification mechanism. Alternatively, the notification processing device 6 connected with the connection device 4 receives the notification signal from the connection device 4, and accordingly enables an air quality processing mechanism.

In an embodiment, the connection device 4 issues a control command to the actuating and sensing device 1 so as to control the operation of the actuating and sensing device 1. Similarly, the control command may be transmitted to the data transceiver 16 through wired or wireless communication as discussed above. Then, the control command is transmitted to the microprocessor 14 to control the sensor 12 to perform the sensing operation and enable the actuating device 13.

In an embodiment, the driving and information transmitting system for the actuating and sensing device 1 further includes a second connection device 9. The second connection device 9 issues the control command to the cloud data processor 8 through the networking relay station 7, then the control command is transmitted from the cloud data processor 8 to the connection device 4 through the networking relay station 7, so that the connection device 4 issues the control command to the data transceiver 16. Then, the control command is transmitted to the microprocessor 14. According to the control command, the microprocessor 14 controls the sensor 12 to perform the sensing operation and enables the actuating device 13. In an embodiment, the second connection device 9 is a device with a wired communication module. In other embodiment, the second connection device 9 is a device with a wireless communication module. In another embodiment, the second connection device 9 is a portable electronic device with a wireless communication module, but not limited thereto.

The actuating and sensing device 1 of the air-filtering protection device may be detached from the filtering mask 2 to form an independent and portable actuating and sensing module for monitoring the air quality. Namely, the actuating and sensing device 1 could monitor the air quality outside the filtering mask 2. The actuating and sensing device 1 is mounted and positioned on the filtering mask 2 and the air-filtering protection device is worn by a user to enclose the air in the mouth and nose of the user by the filtering mask 2. When the actuating device 13 is enabled to transport the air, the air enclosed by the filtering mask 2 is introduced into the interior of the actuating and sensing device 1 through the fluid communication between the first air channel 212 of the first coupling element 21 and the second air channel 103 of the second coupling element 10. Consequently, the air circulation in the air-filtering protection device is enhanced, so that the polluted air in the air-filtering protection device could be exhausted, and the temperature and the humidity of the air could be adjusted by means of exchanging of the air inside and outside of the air-filtering protection device. Since the air enclosed by the air-filtering protection device is monitored by the sensor 12 of the actuating and sensing device 1, the air quality inside the air-filtering protection device could be monitored. The circulation of the air inside the air-filtering protection device could be adjusted to generate different flow rates (e.g. amount of air exhausting) in accordance with the condition of the air quality thereof. Therefore, the air quality inside the air-filtering protection device could be adjusted. When the sensor 12 monitors that the air quality inside the air-filtering protection device is a lasting harm to human beings, a notification signal for replacing a new filtering mask 2 of the air-filtering protection device is issued to the user. After the output data of the monitored data is received by the data transceiver 16, the output data is transmitted from the data transceiver 16 to the connection device 4. The information carried in the output data may be displayed, stored and transmitted by the connection device 4. Consequently, the real-time information may be displayed and a real-time notification may be formed. Moreover, the output data could be uploaded for constructing a cloud database to enable an air quality notification mechanism and an air quality processing mechanism. Therefore, the user could wear the air-filtering protection device immediately to prevent from the ill influence on human health caused by the air pollution.

From the above descriptions, the present disclosure provides an air-filtering protection device combining with an actuating and sensing device. Since the enablement of the actuating device enforces the air circulation and provides with a stable and uniform amount of the air to the sensor, the time for enabling the sensor to monitor the air is largely reduced, thereby achieving the monitoring of the air more precisely. In addition, the actuating and sensing device may not be equipped with a power source itself. Rather, the actuating and sensing device may be coupled to an external power supply device for energy transfer, thereby enabling the sensor and the actuating device. Accordingly, the configuration described above saves a lot of space when installing the entire module, and the purpose of minimizing the design of the module is achieved. Moreover, after the output data of the monitored data is received by the data transceiver, the output data is transmitted from the data transceiver to the connection device. The information carried in the output data may be displayed, stored and transmitted by the connection device. Consequently, the real-time information may be displayed and a real-time notification may be formed. Moreover, the output data could be uploaded for constructing a cloud database to enable an air quality notification mechanism and an air quality processing mechanism. Therefore, the user could wear the air-filtering protection device immediately to prevent from the ill influence on human health caused by the air pollution. In other words, the electronic device of the present disclosure is industrially valuable.

While the invention has been described in terms of what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention needs not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures. 

What is claimed is:
 1. An air-filtering protection device, comprising: a filtering mask being made of a graphene-doping material and being adapted to be worn to filter air, the filtering mask comprising a first coupling element, wherein the first coupling element has a first air channel running through an inner surface and an outer surface of the filtering mask, and a filtering element is disposed in the first air channel; and an actuating and sensing device comprising a second coupling element, the second coupling element being engaged with the first coupling element of the filtering mask for allowing the actuating and sensing device to be detachably mounted on the filtering mask, wherein the actuating and sensing device comprises at least one sensor, at least one piezoelectric pump, a microprocessor, a power controller and a data transceiver, the at least one piezoelectric pump is disposed on one side of the at least one sensor and comprises at least one guiding channel, the at least one piezoelectric pump is enabled to transport an air to flow toward the at least one sensor through the at least one guiding channel so as to make the air sensed by the at least one sensor; wherein the piezoelectric pump is enabled to transport the air in different flow rates in accordance with an air quality information when the actuating and sensing device is mounted on the filtering mask and the filtering mask is worn by a user, so as to adjust the air inside the filtering mask for maintaining the air quality; wherein the piezoelectric pump comprises: a gas inlet plate having at least one inlet, at least one convergence channel and a central cavity defining a convergence chamber, wherein the at least one inlet allows the air to flow in, and the at least one convergence channel is disposed corresponding to the at least one inlet and guides the air from the at least one inlet toward the convergence chamber defined by the central cavity; a resonance plate having a central aperture and a movable part, wherein the central aperture is aligned with the convergence chamber and the movable part surrounds the central aperture; a piezoelectric actuator aligned with the resonance plate; a first insulation plate; a conducting plate; and a second insulation plate; wherein a gap is formed between the resonance plate and the piezoelectric actuator to define a first chamber, so that the air from the at least one inlet of the gas inlet plate is converged to the central cavity along the at least one convergence channel and flows into the first chamber through the central aperture of the resonance plate when the piezoelectric actuator is enabled, whereby the air is further transferred through a resonance between the piezoelectric actuator and the movable part of the resonance plate; wherein the gas inlet plate, the resonance plate, the piezoelectric actuator, the first insulation plate, the conducting plate and the second insulation plate are sequentially stacked.
 2. The air-filtering protection device according to claim 1, wherein the filtering mask is a mouth mask.
 3. The air-filtering protection device according to claim 1, wherein the filtering mask is a wearable face mask and the filtering element made of the graphene-doping material.
 4. The air-filtering protection device according to claim 1, wherein the first coupling element of the filtering mask is a fastening element having at least one tenon.
 5. The air-filtering protection device according to claim 1, wherein the second coupling element is a fastening element having at least one recess and at least one engaging slot.
 6. The air-filtering protection device according to claim 1, wherein the sensor comprises at least one selected from the group consisting of a gas sensor, an oxygen sensor, a carbon monoxide sensor, a carbon dioxide sensor, a liquid sensor, a temperature sensor, a humidity sensor, an ozone sensor, a particulate sensor, a volatile organic compound sensor, a light sensor, a virus sensor, a bacterial sensor and a microbiological sensor.
 7. The air-filtering protection device according to claim 1, wherein the sensor comprises a graphene-sensor.
 8. The air-filtering protection device according to claim 1, wherein the piezoelectric pump is a micro-electro-mechanical system (MEMS) piezoelectric pump.
 9. The air-filtering protection device according to claim 1, wherein the piezoelectric actuator comprises: a suspension plate being a square suspension plate and having a first surface, an opposing second surface and a bulge, wherein the suspension plate is permitted to undergo a bending vibration; an outer frame arranged around the suspension plate; at least one bracket connected between the suspension plate and the outer frame for elastically supporting the suspension plate; and a piezoelectric plate, wherein a length of a side of the piezoelectric plate is smaller than or equal to a length of a side of the suspension plate, and the piezoelectric plate is attached on the first surface of the suspension plate, wherein when a voltage is applied to the piezoelectric plate, the suspension plate is driven to undergo the bending vibration.
 10. The air-filtering protection device according to claim 1, wherein the air quality information including the levels of pollution, humidity and temperature.
 11. The air-filtering protection device according to claim 10, wherein the air quality information is the levels of pollution.
 12. The air-filtering protection device according to claim 1, wherein the power controller of the actuating and sensing device comprises a charging element for storing and outputting energy for powering the sensor to perform a sensing operation and powering the piezoelectric pump to perform an actuating operation.
 13. The air-filtering protection device according to claim 12, wherein the charging element transfers the energy through a wired transmission path.
 14. The air-filtering protection device according to claim 12, wherein the charging element transfers the energy through a wireless transmission path.
 15. The air-filtering protection device according to claim 1, wherein the microprocessor of the actuating and sensing device computes a monitored data of the at least one sensor and converts the monitored data into an output data, the output data is received by the data transceiver, the output data is transmitted from the data transceiver to a connection device, and the information carried by the output data is displayed, stored and transmitted by the connection device.
 16. The air-filtering protection device according to claim 15, wherein the connection device is connected with a notification processing system to enable an air quality notification mechanism.
 17. The air-filtering protection device according to claim 15, wherein the connection device is connected with a notification processing device to enable an air quality processing mechanism.
 18. An air-filtering protection device, comprising: at least one filtering mask being made of a graphene-doping material and being adapted to be worn to filter air, the at least one filtering mask comprising at least one first coupling element wherein the first coupling element has a first air channel running through an inner surface and an outer surface of the filtering mask, and a filtering element is disposed in the first air channel; and at least one actuating and sensing device comprising at least one second coupling element, the at least one second coupling element being engaged with the at least one first coupling element of the filtering mask for allowing the at least one actuating and sensing device to be detachably mounted on the at least one filtering mask, wherein the at least one actuating and sensing device comprises at least one sensor, at least one piezoelectric pump, at least one microprocessor, at least one power controller and at least one data transceiver, the at least one piezoelectric pump is disposed on one side of the at least one sensor and comprises at least one guiding channel, the at least one piezoelectric pump is enabled to transport at least one air to flow toward the at least one sensor through the at least one guiding channel so as to make the air sensed by the at least one sensor; wherein the at least one piezoelectric pump is enabled to transport the air in different flow rates in accordance with an air quality information when the at least one actuating and sensing device is mounted on the at least one filtering mask and the at least one filtering mask is worn by a user, so as to adjust the air inside the at least one filtering mask for maintaining the air quality; wherein each of the at least one piezoelectric pump comprises: a gas inlet plate having at least one inlet, at least one convergence channel and a central cavity defining a convergence chamber, wherein the at least one inlet allows the air to flow in, and the at least one convergence channel is disposed corresponding to the at least one inlet and guides the air from the at least one inlet toward the convergence chamber defined by the central cavity; a resonance plate having a central aperture and a movable part, wherein the central aperture is aligned with the convergence chamber and the movable part surrounds the central aperture; a piezoelectric actuator aligned with the resonance plate; a first insulation plate; a conducting plate; and a second insulation plate; wherein a gap is formed between the resonance plate and the piezoelectric actuator to define a first chamber, so that the air from the at least one inlet of the gas inlet plate is converged to the central cavity along the at least one convergence channel and flows into the first chamber through the central aperture of the resonance plate when the piezoelectric actuator is enabled, whereby the air is further transferred through a resonance between the piezoelectric actuator and the movable part of the resonance plate; wherein the gas inlet plate, the resonance plate, the piezoelectric actuator, the first insulation plate, the conducting plate and the second insulation plate are sequentially stacked. 